Green Flame-Retardant Blend Used to Improve the Antiflame Properties of Polypropylene.

The flammability properties of polymers and polymeric composites play an important role in ensuring the safety of humans and the environment; moreover, flame-retardant materials ensure a greater number of applications. In the present study, we report the obtaining of polypropylene (PP) composites contain a mixture of two green flame retardants, lignin and clinoptilolite, by melt extrusion. These additives are abundantly found in nature. Fourier transform infrared (FT-IR), thermogravimetric analysis (TGA), mechanical properties, scanning electron microscopy-energy dispersive X-ray spectroscopy (SEM-EDS), cone calorimetry, UL-94, and carbonized residues analysis were carried out. TGA analysis shows that PPGFR-10 and PPGFR-20 compounds presented better thermal stability with respect to PP without flame retardants. The conical calorimetric evaluation of the composites showed that PPGFR-10 and PPGFR-20 presented decreases in peak heat release rates (HRRs) of 9.75% and 11.88%, respectively. The flammability of the composites was evaluated with the UL-94 standard, and only the PPGFR-20 composite presented the V-0 and 5VB classification, which indicates good flame-retardant properties. Additives in the polymer matrix showed good dispersion with few agglomerates. The PPGFR-20 composite showed an FRI value of 1.15, higher percentage of carbonized residues, and UL-94 V-0 and 5VB rating, suggesting some kind of synergy between lignin and clinoptilolite, but only at high flame-retardant concentrations.

Biosorption of Cadmium by Non-Toxic Extracellular Polymeric Substances (EPS) Synthesized by Bacteria from Marine Intertidal Biofilms.

Cadmium is a major heavy metal found in polluted aquatic environments, mainly derived from industrial production processes. We evaluated the biosorption of solubilized Cd2+ using the extracellular polymeric substances (EPS) produced by Bacillus sp. MC3B-22 and Microbacterium sp. MC3B-10 (Microbactan); these bacteria were originally isolated from intertidal biofilms off the coast of Campeche, Mexico. EPS were incubated with different concentrations of cadmium in ultrapure water. Residual Cd2+ concentrations were determined by Inductive Coupled Plasma-Optic Emission Spectrometry and the maximum sorption capacity (Qmax) was calculated according to the Langmuir model. EPS were characterized by X-ray photoelectron spectroscopy (XPS) before and after sorption. The Qmax of Cd2+ was 97 mg g-1 for Microbactan and 141 mg g-1 for MC3B-22 EPS, these adsorption levels being significantly higher than previously reported for other microbial EPS. In addition, XPS analysis revealed changes in structure of EPS after biosorption and showed that amino functional groups contributed to the binding of Cd2+, unlike other studies that show the carbohydrate fraction is responsible for this activity. This work expands the current view of bacterial species capable of synthesizing EPS with biosorbent potential for cadmium and provides evidence that different chemical moieties, other than carbohydrates, participate in this process.

Biogenic black crusts on buildings in unpolluted environments.

Samples of peeling black crusts from modern and historic buildings in Campeche, Mexico, from a gravestone on the island of Dom Khon, Lao, and from the Anglican cathedral in Belize City were analyzed microbiologically, by scanning electron microscopy plus electron dispersive spectroscopy (EDS) and for pigment composition. In all cases, the surface was covered by a thick mat of cyanobacteria with dark brown sheaths. These were filamentous organisms of the genera Scytonema or Fischerella/Mastigocladus, except for one sample, where coccoid cyanobacteria of Subsection II were predominant. Fungi were not present at all sites and, where seen, were not the major biomass. High scytonemin:chlorophyll a ratios correlated with the dark pigmentation of the cyanobacterial cells and indicated the stressful conditions under which these organisms were living (high temperatures and ultraviolet levels, frequent desiccation). The absence, or low levels, of sulfur in the biofilms confirmed that there was little urban pollution at the sites and the EDS analysis showed that the black coloration was caused solely by cell pigmentation; no dark-colored elements were present at high concentrations. These results demonstrate that, unlike chemically formed thick black crusts found in polluted atmospheres, thin black crusts (which could be called patinas) in clean environments may be predominantly composed of filamentous cyanobacteria.